[0001] Vegetables and fruit such as apples, pears, tomatoes, citrus fruits and the like
are selected in current practice on the basis of a large number of parameters, such
as size, weight, colour and the like. Because of increasing demands of consumers,
there is now a trend toward also sorting fruits and vegetables according to hardness.
[0002] It is the current practice at auctions for an inspector to determine the hardness
of a fruit in usually destructive manner by means of penetration with an impactor
through about 2 cm. This hardness can have different values at different locations
on the fruit. In the classification and selection of fruits there is therefore a need
to determine the hardness of a fruit on the surface in non-destructive manner, for
instance by means of non-destructive impact (or hardness) measurements.
[0003] In the international patent application PCT/GB98/01300 an impactor in a bellows is
carried above one fruit or vegetable at a time, whereafter the local hardness derived
from the elasticity is determined from the impact measured with a piezo-electric element.
[0004] This known method and device is however not suitable for performing measurements
on fruits being supplied on a conveyor at a high speed, since the bellows must be
brought close to the fruit each time. The hardness (or elasticity) of the fruit is
furthermore determined at only one position, which provides an unreliable indication
of the general hardness (and/or ripeness) of that fruit.
[0005] The present invention provides a method for determining the hardness of a vegetable
or fruit, wherein the vegetable or fruit is rotated, wherein an impactor element is
carried close to the surface of a fruit or vegetable, wherein during rotation of the
fruit an impactor element is brought into contact with the fruit or the vegetable
a number of times, wherein the impact ofthe respective impactor element is measured
in order to determine the hardness of the vegetable or fruit over at least a portion
of the surface thereof.
[0006] The impactor element preferably co-displaces with the fruit above the conveyor in
order to enable a large number of measurements over the surface thereof while the
fruit is supplied by the supply conveyor.
[0007] In another preferred embodiment of the method and device according to the present
invention, it is likewise conceivable for a number of impactor elements to be in successive
stationary disposition while the fruits are transported rotatingly thereunder (or
over) on a conveyor. It is of course of equal importance here that the impactor elements
can properly follow the contours of successive fruits or vegetables of perhaps differing
diameter, for which purpose it is important that the impactor elements are freely
movable in vertical direction.
[0008] The present invention further provides a device for determining the hardness of a
vegetable or fruit, comprising:
- a supply conveyor for supplying the vegetables or fruits,
- rotation means for causing the vegetables or fruits to rotate on the supply conveyor;
and
- one or more hardness measuring members for measuring the hardness of the vegetables
or fruits during rotation thereof, wherein the hardness measuring members are arranged
above the supply conveyor.
[0009] In a further preferred embodiment of the device according to the present invention
the hardness measuring members are arranged pivotally relative to each other or movable
in height independently of each other in order to perform reliable hardness measurements
on successive vegetables or fruits of different size.
[0010] In a first preferred embodiment the impactor element is lifted using a solenoid and
then released, whereafter the impact thereof is measured using a piezo--electric transducer;
in other embodiments mechanical lifting of the weight on the impactor element can
also take place, wherein the impact is likewise determined by means of a piezo-electric
transducer or with other means.
[0011] In a further preferred embodiment the hardness or impact transducer is arranged adjacently
to a wheel or disc which rolls along the surface of a fruit and which, irrespective
of the diameter thereof, prevents damage to this fruit. In the embodiment wherein
the transducer co-displaces with the fruit, the hardness can be determined at any
desired location along the surface, which increases the flexibility of the number
of measurements and the speed of the conveyor.
[0012] The method and device according to the present invention can also be applied for
other measurement principles, such as to determine the spectrum of the light reflected
by the surface of a vegetable or fruit, the spectrum of the light passing through
the object, the roughness of the skin of a vegetable or fruit, the analysis of the
gases given off by the object and the like.
[0013] The present invention therefore also provides a method for determining a property
of a vegetable or fruit, wherein the vegetable or fruit is rotated, wherein during
rotation of the fruit the transducer is brought a number of times into the vicinity
of the fruit or the vegetable, wherein the property is measured, in order to determine
the property of a vegetable or fruit over at least a portion of the surface thereof.
[0014] The present invention further provides a device for performing such a method.
[0015] In order to prevent an (elongate) fruit which is supplied on a brush roller being
forced laterally out of the conveyor path due to contact with a wheel or transducer,
in accordance with another aspect the present invention provides a brush roller with
one or more, preferably two, rings of slip-resistant material such as rubber. In a
further preferred embodiment a sensor element or contact element is arranged between
two diabolo-shaped elements in order to position the fruits properly and to obtain
a reliable and accurate measuring result.
[0016] Further advantages, features and details of the present invention will be elucidated
on the basis of the following description with reference to the annexed drawings,
in which:
figure 1 shows a schematic view in perspective of a preferred embodiment of the device
and method according to the present invention;
figure 2 shows a perspective view of detail II of figure 1;
figure 3 is a front view in perspective of detail III of figure 2;
figures 4A - 4E are schematic side views of respective alternative embodiments of
an impactor element to be applied in the embodiment according to figure 1;
figure 5 shows a schematic side view of a further preferred embodiment of a device
and method according to the present invention;
figure 6 shows a view of a further preferred embodiment of the device as according
to figures 1, 2 and 3;
figure 7 shows a schematic view of a further preferred embodiment of a method and
device according to the present invention;
figures 8, 9 and 10 are respective schematic views of further preferred embodiments
of a method and device according to the present invention;
figure 11 is a view of a brush roller with two slip-resistant rings;
figures 12 and 13 show further preferred embodiments of a part of a device according
to the present invention; and
figure 14 is a schematic side view of another preferred embodiment of a device according
to the present invention.
[0017] In a sorting line 1 (figure 1) fruits V
1, V
2 and V
3, for instance of differing size, are supplied in the direction of arrow A on a conveyor
3 provided with diabolos 2. Using a belt, rope or chain 4 driven in the direction
of arrow B, the diabolos are rotated in a direction according to arrow C, whereby
the fruits rotate in the direction of arrow D. The rotation direction D of the fruits,
which is in fact in the direction opposite to transporting direction A, is recommended
since, as will become apparent hereinbelow, the hardness of the fruits is determined
by means of mechanical contact. The advantage of this transporting direction is that
the fruit displaces little during the momentary mechanical contact, less damage to
the fruits will occur and/or the influence of occurring lateral forces will be less
in evidence.
[0018] The above stated advantage is particularly important in a stationary disposition
(not further shown), wherein a number of contact elements is disposed successively
above the conveyor with diabolos. In the embodiment shown in figure 1, wherein the
contact elements co-displace, it is also possible to envisage the fruits being rotated
forward.
[0019] Arranged above conveyor 3 is a device 10 which comprises a number of contact elements
11 which are connected mutually pivotally and which are also provided on the ends
with one or more discs or wheels 12 to allow such an element 11 to roll over a fruit
V
1-V
3.
[0020] Reversing wheels 7 respectively 9 are driven using a schematically designated motor
8 in order to drive the contact elements 11 in the direction of arrow E at substantially
the same speed as the transporting speed of conveyor 3, i.e. synchronously therewith.
As shown particularly clearly in figures 2 and 3, a pin 13 with a weight member 14
of predetermined value, for instance 10 grammes, is situated in each case adjacently
of a disc or wheel 12, wherein the weight is held in the rest position by a helical
pressure spring 15. While a contact element-11 co-displaces with a determined fruit,
a solenoid (not further shown) is released at predetermined times, whereby the weight
14 of predetermined mass on the impactor element drops against the surface of a fruit
V
1, V
2 or V
3, whereby the degree of impact of that weight against the fruit, and thus the hardness
of this fruit, can be determined by a piezo-electric transducer (not shown). An example
of the co-action of a solenoid and piezo-electric element is described in for instance
the above stated international patent application.
[0021] Because the contact elements co-displace with the conveyor and the fruit is simultaneously
rotated, the hardness of the fruit can for instance be measured at 10 or more locations
along the whole periphery of this fruit. In the case of small fruits a smaller number
of measurements may already suffice.
[0022] As shown particularly in figure 3, contact element 11 comprises two parallel arms
21, 22 with a connecting piece 23 arranged therebetween, wherein the solenoid and
the piezo-electric element are arranged in a manner not shown. An electric lead 24
is also connected to this connecting piece 23. Pairs of curved arms 25, 26 respectively
27, 28, together forming a parallelogram, are further arranged pivotally on the mounting
arm, while in the present embodiment a damper 29 (and/or a spring) is arranged between
arms 27 and 28 in order to prevent damage to the fruits and/or optimize the response
of the impactor. A subsequent contact element 11 can be mounted pivotally on contact
element 11, as elucidated in figures 1 and 2, so that the successive contact elements
11 can follow the fruits of differing diameter as well as possible.
[0023] In another, not shown, preferred embodiment the contact elements can likewise be
mounted directly on a chain or toothed belt, wherein it must however be ensured that
the contact elements can move sufficiently in vertical direction.
[0024] In the embodiments according to figures 4A, 4C, - 4D and 4E are shown schematic alternatives
to the embodiment according to figure 4B. In figure 4A a weight 14 is moved mechanically
upward in each case using parallel arms 41, 42 and a curve disc 43, while this mechanical
transport is realized according to figure 4C using a curve 44 arranged internally
on a disc 45, whereby the mass with the piezo-element is raised, whereafter it falls
freely onto the inner side of the wheel. The pulse of the impact transmitted by the
wheel to the measured product is measured by the piezo-element.
[0025] In the embodiment according to figure 4D a weight 46 is moved upward using a tooth
path 47 and a cam 48, whereafter it can fall, while in order to avoid damage to the
fruits a damper 49 can also be arranged. In the embodiment of figure 4E the damping
can be obtained in a manner corresponding to the embodiment shown in figures 1-3.
[0026] The preferred embodiments applied in figures 4A-4E can likewise be applied in a stationary
arrangement, i.e. wherein a number of such impactor elements is disposed mutually
adjacently above the conveyor provided with diabolos, wherein the fruits are rotated
and are measured in each case at a further location on the periphery thereof under
a following impactor element.
[0027] In the preferred embodiment shown in figure 5 the fruits V' of different diameter
are transported in the direction of arrow G on a conveyor provided with diabolos 51,
wherein impactor element 52 co-displaces between the diabolos 51 and during rotation
of fruits V' a contact element 53 is jolted upward each time against fruits V' with
a predetermined impulse, wherein in the manner described above the impact thereof
is measured with for instance a piezo-electric element.
[0028] In the embodiment shown in figure 6, which forms a further development of the embodiment
shown in figures 1, 2 and 3, each contact element 61 is provided-with a single disc
62, within the periphery of which the impactor members 63 are arranged in each case.
The construction 64, which enables elements 61 to move as freely as possible in vertical
direction, is arranged on pins 65 which are advanced between chains 66 and 67 synchronously
with the conveyor with diabolos, not shown in figure 6.
[0029] In the embodiment according to figure 7 light is projected onto a fruit F rotated
by transport rollers 73 using two light sources 71, 72, the reflection of which light
is determined using an optical transducer 74 arranged adjacently of a wheel 75 which
follows the surface of fruit F. Connected to transducer 74 is a glass fibre cable
78 which is connected on the other side to an analysis device 76 for analysing the
spectrum of the reflected light, on the basis of which an output signal 77 is generated
by analysis device 76, which signal is a measure for the colour of the fruit.
[0030] In the device 80 according to figure 8 light is projected between two transport rollers
82, 83 onto a fruit G by a light source 81, whereby fruit G is rotated, while the
quantity of light let through by fruit G is measured by a transducer 84 which is connected
to a spectral analyser 86 via a glass fibre cable 85, the output signal 87 of which
analyser provides a measure for the quantity of light let through by the object.
[0031] In the device 90 according to figure 9 a fruit H set into rotation by transport rollers
91 and 92 is scanned using a scanning member 93, which is arranged adjacently of a
tracking wheel 94 in order to enable determining of the roughness of the surface of
fruit H from the movements of scanning member 93.
[0032] In the device 100 of figure 10, wherein a fruit I is rotated by transport rollers
101, 102, the gases given off by fruit I are taken up using a sniffer member 104 arranged
adjacently of a tracking wheel 103 and guided further via a hose 105 to a gas analysis
device 106 for the purpose of generating an electrical signal 107 which forms a measure
for the quantity and/or composition of the gases given off by a fruit, and thus for
instance for the ripeness thereof.
[0033] In the case of for instance elongate and vulnerable fruits, such as avocados and
pears, which are usually supplied on brush rollers, the problem can occur of these
fruits being urged sideward when there is contact with a wheel on the upper side.
In order to prevent this the brush roller 110 of figure 11 is provided with two rubber
rings 111, which ensure that a fruit undergoes sufficient lateral resistance.
[0034] In a further preferred embodiment according to figures 12 and 13 sensor elements
121, 122 and 123 are arranged between diabolo-shaped brushes 124 and 125, the density
of which is different. The diabolo-shaped brushes enable good positioning of the fruits
and an accurate and reliable measuring result can be obtained.
[0035] Dependent on the type of fruits, the rotating elements can however also be a diabolo-shaped
smooth surface or even be provided with a flat surface of for instance plastic or
rubber, which can also be locally rough.
[0036] In the embodiment of fig. 14 the apples are supplied on diabolos 131 in the direction
of arrow T. Sensors 132 are arranged on an endless belt 133 in the direction of arrows
U which is moved synchronously with diabolos 131 such that the sensors protrude in
each case precisely therebetween. This embodiment is particularly advantageous with
batches of fruits with very large difference in dimensions.
[0037] The present invention is not limited to the above described preferred embodiment
thereof; the rights sought are defined by the following claims, within the scope of
which many modifications can be envisaged.
1. Method for determining the hardness of a vegetable or fruit, wherein the vegetable
or fruit is rotated, wherein an impactor element is carried close to the surface of
a fruit or vegetable, wherein during rotation of the fruit an impactor element is
brought into contact with the fruit or the vegetable a number of times, wherein the
impact of the respective impactor element is measured in order to determine the hardness
of the vegetable or fruit over at least a portion of the surface thereof.
2. Method as claimed in claim 1, wherein the impact is determined using a (piezo-electric)
transducer.
3. Method as claimed in claim 1 or 2, wherein the fruit or vegetable is transported over
a conveyor and wherein the impactor element co-displaces with the fruit.
4. Device for determining the hardness of a vegetable or fruit, comprising:
- a supply conveyor for supplying the vegetables or fruits,
- rotation means for causing the vegetables or fruits to rotate on the supply conveyor;
and
- one or more hardness measuring members for measuring the hardness of the vegetables
or fruits during rotation thereof, wherein the hardness measuring members are arranged
above the supply conveyor.
5. Device as claimed in claim 4, wherein a number of hardness measuring members are arranged
successively and are coupled to drive means for driving thereof at substantially the
same speed as the supply conveyor.
6. Device as claimed in claim 4 or 5, wherein successive hardness measuring members are
arranged pivotally relative to each other.
7. Device as claimed in claim 4, 5 or 6, wherein a hardness measuring member comprises
a solenoid and a transducer.
8. Device as claimed in any of the claims 4-7, wherein hardness measuring members comprise
a spring member and/or damping member.
9. Device as claimed in any of the claims 4-7, wherein a hardness measuring member comprises
an (endless) tooth path or curve discs.
10. Method for determining a property of a vegetable or fruit, wherein the vegetable or
fruit is rotated, wherein during rotation of the fruit the transducer is brought a
number of times into the vicinity of the fruit or the vegetable, wherein the property
is measured, in order to determine the property of a vegetable or fruit over at least
a portion of the surface thereof.
11. Device for determining a property of a vegetable or fruit, comprising:
- a supply conveyor for supplying the vegetables or fruits, rotation means for causing
the vegetables or fruits to rotate on the supply conveyor; and
- one or more sensor members for measuring the property of the vegetables or fruits
during rotation thereof.
12. Device as claimed in claim 11, wherein the sensor members are arranged adjacently
of one or more wheels.
13. Device for performing the method as claimed in any of the claims 1, 2, 3 or 10.
14. Device as claimed in claim 11, 12 or 13, wherein the supply conveyor is provided with
brush rollers with slip-resistant means.
15. Brush roller with slip-resistant means for use in a device for classifying vegetables
or fruit.